The FE-M Task Force: 3D modelling of THM repository induced effects in the Full-scale Emplacement Experiment (FE) &ndash; Mont Terri Rock Laboratory. Current status and the path forward.

Andres Alcolea; Ivan P. Damians; Berrak Firat-Lüthi; Benoit Garitte; Antonio Gens; Olaf Kolditz; Lyesse Laloui; Bill Lanyon; Aldo Madaschi; Paul Marschall; Thomas Nagel; Sebastia Olivella; Andreas Reinicke; Hua Shao; Wenqing Wang; Matthias Wojnarowicz

doi:https://doi.org/10.5194/egusphere-egu22-13385

[Back] [Session ERE3.5]

EGU22-13385, updated on 28 Mar 2022

https://doi.org/10.5194/egusphere-egu22-13385

EGU General Assembly 2022

© Author(s) 2022. This work is distributed under
the Creative Commons Attribution 4.0 License.

The FE-M Task Force: 3D modelling of THM repository induced effects in the Full-scale Emplacement Experiment (FE) – Mont Terri Rock Laboratory. Current status and the path forward.

Andres Alcolea¹, Ivan P. Damians², Berrak Firat-Lüthi³, Benoit Garitte⁴, Antonio Gens², Olaf Kolditz⁵, Lyesse Laloui⁶, Bill Lanyon⁷, Aldo Madaschi⁸, Paul Marschall³, Thomas Nagel⁹, Sebastia Olivella², Andreas Reinicke³, Hua Shao¹⁰, Wenqing Wang⁵, and Matthias Wojnarowicz⁶

Andres Alcolea et al.

¹HydroGeoModels AG; Seuzach, Switzerland
²Universitat Politècnica de Catalunya (UPC–CIMNE); Barcelona, Spain
³Nationale Genossenschaft für die Lagerung radioaktiver Abfälle (NAGRA); Wettingen, Switzerland
⁴Amberg Engineering S.A.; Lausanne, Switzerland
⁵Department of Environmental Informatics, Helmholtz Center for Environmental Research; Leipzig, Germany
⁶Ecole Polytechnique Fédérale de Lausanne (EPFL), Laboratory for Soil Mechanics (LMS), EPFL-ENAC-LMS; Lausanne, Switzerland
⁷Fracture Systems Ltd; St Ives, UK
⁸Numerical Engineering Solutions Sàrl; Lausanne, Switzerland
⁹Chair of Soil Mechanics and Foundation Engineering, Geotechnical Institute, Technische Universität Bergakademie Freiberg; Freiberg, Germany
¹⁰Federal Institute for Geosciences and Natural Resources (BGR); Hannover, Germany

The construction and operational phases of a deep geological repository imply potential perturbations of the host rock, so-called Repository Induced Effects (RIE). Amongst them, spent fuel and high level waste (SF/HLW) produce decay heat even after long times of cooling, which may impair the long-term safety of the Engineered Barrier System and of the geological barrier. The Opalinus Clay (OPA), is currently being assessed as host rock for the deep geological repository in Switzerland. OPA is an indurated clay of Jurassic age (ca. 180 My), whose main features are (1) a very low hydraulic conductivity, (2) an excellent retention capacity for dissolved radionuclides, and (3) a significant self-sealing capacity.

The on-going Full-scale Emplacement (FE) Experiment at the Mont Terri Underground Rock Laboratory simulates, as realistically as possible, the construction, waste emplacement, backfilling and early-stage post-closure evolution of a single SF/HLW emplacement tunnel in OPA, using heaters instead of disposal canisters. The main goal of the FE experiment is the investigation of RIE on the host rock (and, to a lesser extent, on the the backfill material) at true scale and the validation of existing coupled thermo-hydro-mechanical (THM) models. In this context, Nagra has developed a new RD&D initiative, i.e., the FE modelling Task Force (FE-M TF), which involves three modelling teams with corresponding software packages (Code Aster, Code Bright and OpenGeoSys). So far, the TF has defined three main tasks:

Code comparison and calculation verification: the TF designed a simplified (though realistic) 3D conceptual model of the FE experiment that includes the actual geometry of the main elements, materials and phases of the FE experiment, including tunnel excavation and ventilation. Such conceptual model was implemented by the modelling teams. Finally, code outputs were analysed and compared by the TF.
Back-analyses of THM-observations in the host rock: monitoring data from radial
and oblique boreholes around the backfilled FE tunnel are used for model calibration,
including the derivation of parameter best estimates and inherent uncertainties, and model
Model validation in the context of a prediction-evaluation exercise: the evolution
of the THM conditions in the rock in response to a change of thermal loads (e.g., increase/decrease of heater output) will be predicted using the calibrated models. Finally, model predictions will be validated in the near future using the acquired measurements.

This presentation summarizes the current status of Tasks 1 and 2 and the path forward to Task 3.

How to cite: Alcolea, A., Damians, I. P., Firat-Lüthi, B., Garitte, B., Gens, A., Kolditz, O., Laloui, L., Lanyon, B., Madaschi, A., Marschall, P., Nagel, T., Olivella, S., Reinicke, A., Shao, H., Wang, W., and Wojnarowicz, M.: The FE-M Task Force: 3D modelling of THM repository induced effects in the Full-scale Emplacement Experiment (FE) – Mont Terri Rock Laboratory. Current status and the path forward., EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-13385, https://doi.org/10.5194/egusphere-egu22-13385, 2022.

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